How to access the current iteration number in the program where we supply the non-linear equations,F =0 and the Jacobian for FSOLVE?

4 visualizzazioni (ultimi 30 giorni)
Rahul Gulati
Rahul Gulati il 15 Set 2020
Commentato: Ameer Hamza il 15 Set 2020
For example, in the sample code for fsolve:
fun = @root2d;
x0 = [0,0];
x = fsolve(fun,x0)
where :
function F = root2d(x)
current_iteration= ?
F(1) = exp(-exp(-(x(1)+x(2)))) - x(2)*(1+x(1)^2);
F(2) = x(1)*cos(x(2)) + x(2)*sin(x(1)) - 0.5;
In the code root2d, if my non linear problem formulation depends on the current iteration, how can i access the present iteration number?
I understand that once all the iterations have been completed, we can get the total number of iterations for convergence using 'output paramter' but this is not what i want.
  2 Commenti
Ameer Hamza
Ameer Hamza il 15 Set 2020
Can you show an example of where this might be relevant? The problem definition is usually independent of the algorithm. Different algorithms will take a different number of iterations to reach the same optimal solution. How can you use the iteration number in the equations in any useful way?
Rahul Gulati
Rahul Gulati il 15 Set 2020
Modificato: Rahul Gulati il 15 Set 2020
I am solving a set of non linear equations for a finite element code. At each increment, for the first iteration, i need to add some terms to the non linear equations (this will apply 'displacement boundary condition'). This value will be zero for all the following iterations (except for the first iteration). To be able to add a term only for the first iteration, i want to access the current iteration.

Accedi per commentare.

Accedi per rispondere a questa domanda.

Risposta accettata

Ameer Hamza
Ameer Hamza il 15 Set 2020
Modificato: Ameer Hamza il 15 Set 2020
Something like this will work
global iter_number % global variable for a quick example, i recommend creating a handle class object
iter_number = 0;
fun = @root2d;
x0 = [0,0];
opts = optimoptions('fsolve', 'OutputFcn', @outputFcn);
x = fsolve(fun,x0, opts);
root2d(x)
function F = root2d(x)
global iter_number
current_iteration = iter_number
F(1) = exp(-exp(-(x(1)+x(2)))) - x(2)*(1+x(1)^2);
F(2) = x(1)*cos(x(2)) + x(2)*sin(x(1)) - 0.5;
end
function stop = outputFcn(x, optimValues, state)
global iter_number
iter_number = optimValues.iteration;
stop = 0;
end

Più risposte (0)

Categorie

Scopri di più su Nonlinear Optimization in Help Center e File Exchange

Tag

Community Treasure Hunt

Find the treasures in MATLAB Central and discover how the community can help you!

Start Hunting!

Translated by